Activation of rock avalanches in the Central Caucasus and their impact on the dynamics of glaciers and debris flows

We analyzed multi-time satellite images of the Central Caucasus glacial zone and interpreted more than thirty rock avalanche events in the 21st century with a total damage area of more than 25 km² (including the collapse zone of the Kolka Glacier disaster). The highest rock and rock-ice avalanche activity is detected in the section of The Greater Caucasus range (northern and southern slopes) with a length of about 20 km between the Bashkara and Kulaktau peaks (16 rock avalanches) and in the section of the Kazbek-Dzhimaray Massif (series of rock avalanches to the surface of Kolka, Suatisi and Devdoraki glaciers). The feature of the rock and ice-rock avalanches is the large runout distance. For 12 events (about 40%) the distance was more than 2000 m. One ice-rock avalanche from the Mount Kazbek (excluding the Kolka Glacier disaster in 2002) reached the runout distance more than 10 km. In some areas, the rock avalanches occurred several times. In particular, a large number of avalanches were in the cirque of the Kolka Glacier; the last of them at the end of 2019. Thrice шт each case, rock avalanches originated from Mount Bashkara, in the cirques of the Murkvam Glacier, the East Shtulu Glacier, and the Devdoraki Glacier. Ice and rock avalanches were the initial stage of the complex process of the Kolka Glacier disaster and following catastrophic glacial debris flow in the Genaldon/Gizeldon River valley in 2002. Also, they were causes of glacier surges, formation of dammed lakes, and debris flows. As a result of the collapse of the hanging glacier and bedrock, the former right tributary of the Kolka Glacier surged to 200 m in 2006. Ice-rock avalanche from Mount Kazbek in 2014 load up the former right tributary of the Devdoraki Glacier and caused its advancing in 2015–2019, at a distance of more than 400 m. The avalanches caused catastrophic debris flows in the Amilishka/Kabakhi River valley in 2014, the Mestiachala River valley in 2019. Rock avalanches can cause outbursts of lakes and debris flows. Two dammed lakes formed as a result of the rock avalanche from the cirque above the Seri Glacier in the Tviberi River valley of the in May 2016. The lakes (total area was more than 0.05 km²) have outburst at the end of August 2017 after heavy rains. Rock avalanches of the 20th century led to an abrupt deceleration in the retreat of the Yusengi, Bartuytsete, East Shtulu and Mosota glaciers. The formation of rock avalanches in the 21st century took place at high altitudes (an average of about 3900 m). Possibly, the reason was associated with an increase of the «0» isotherm and of the high border of the zone of intense frost weathering due to climate warming. Some rock avalanches in the section of the Kazbek-Dzhimarai Massif have been caused by endogenous factors (seismicity and volcanism).

debris flow, glacial lake outburst flood, glacier collapse, glacier surge, ice-rock avalanche, rock slope failure,

1. Strom A.L., Zhirkevich A.N. Reconstruction of debris floods caused by breach of the prehistoric rockslide dams in Central Asia and their parameters assessment. Selevye potoki: katastrofy, risk, prognoz, zashita. Debris Flows: Disasters, Risk, Forecast, Protection. Proceedings of the 5th International Conference. Tbilisi, Georgia, 1–5 October 2018. Eds.: S.S. Chernomorets, G.V. Gavardashvili. Tbilisi: Publishing House «Universal», 2018: 182–192.

2. https://blogs.agu.org/landslideblog/.

3. https://twitter.com/inrushmd/status/1132861019141939200.

4. Duhar P., Sepulveda V., Garrido N., Mella M., Quiroz D., Fernаndez J., Moreno H., Hermosilla G. The Santa Lucia landslide disaster, Chaiten-Chile: origin and effects. Debris-flow hazards mitigation: Mechanics, Monitoring, Modeling, and Assessment. Proceedings of the Seventh International Conference on Debris-Flow Hazards Mitigation, Golden, Colorado, USA, June 10–13. 2019: 653–660.

5. Walter F., Amann F., Kos A., Kenner R., Phillips M., Preux A., Huss M., Tognacca C., Clinton J., Diehl T., Bonanomi Y. Direct observations of a three million cubic meter rock-slope collapse with almost immediate initiation of ensuing debris flows. Geomorphology. 2020, 351. Article. 106933. https:// doi.org/10.1016/j.geomorph.2019.106933.

6. Byers A.C., Rounce D.R., Shugar D.H., Lala J.M., Byers E.A. Regmi D. A rockfall-induced glacial lake outburst flood, Upper Barun Valley, Nepal. Landslides. 2019, 16: 533–549.

7. Hancox G.T., Thomson R. The January 2013 Mt Haast Rock Avalanche and Ball Ridge Rock Fall in Aoraki/ Mt Cook National Park, New Zealand. GNS Science Report. 2013, 33: 26 p.

8. Valderrama P., Vilca O. Dinamica e implicancias del aluvión de la laguna 513, Cordillera Blanca, Ancash Perú. Revista de la Asociación Geológica Argentina. 2012, 69 (3): 400–406.

9. Schoeneich P., Hantz D., Amelot F., Deline P. A new database of alpine rock falls and rock avalanches. INTERPRAEVENT 2008 – Conf. Proc. 2008, 2: 243–250.

10. Dokukin М. D., Savernyuk E.A., Chernomorets S.S. Rock Avalanches in the Alpine Zone of the Caucasus in the 21 Century. Priroda. Nature. 2015, 7: 52–62. [In Russian].

11. Dokukin M.D., Kalov Kh.M., Savernyuk E.A. Large rock slope failures activation in the high-mountain zone of the western Caucasus in the 21st century (analysis of multitemporal satellite images). Aktual'nye napravleniya sbalansirovannogo razvitiya gornykh territoriy v kontekste mezhdisciplinarnogo podkhoda: Materialy I Mezhdunarodnoy nauchnoy konferentsii. Actual directions of balanced mountain development in the context of an interdisciplinary approach: Materials of the I Intern. Scientific Conf. Karachaevsk: KCHU, 2019: 61–66. [In Russian].

12. Dokukin M.D., Kalov R.Kh., Chernomorets S.S., Gyaurgiev A.V., Khadzhiev M.M. The snow ice rock avalanche on Bashkara glacier in the Adyl-Su valley (Central Caucasus) on april 24, 2019. Kriosfera Zemli. Earth’s Cryosphere. 2020, 24 (1): 64–70. doi: 10.21782/KZ1560-7496-2020-1(64-70). [In Russian].

13. Hungr O., Leroueil S., Picarelli L. The Varnes classification of landslide types, an update. Landslides. 2014, 11: 167–194. https://doi.org/10.1007/s10346-013-0436-y.

14. Sosio R. Rock–snow–ice avalanches. Landslide Hazards, Risks and Disasters. Ch. 7. Amsterdam: Elsevier, 2015: 191–240.

15. Sochineniya Aleksandra Pushkina. Tom tretiy. Sanktpeterburg, v tipografii zagotovleniya gosudarstvennykh bumag. Works of Alexander Pushkin. Volume Three. St.Petersburg, in the printing house of government securities. MDCCCXXXVIII. Obval: 75–76 http://lib. pushkinskijdom.ru. [In Russian].

16. Katalog lednikov SSSR. USSR Glacier Inventory. V. 8. Pt. 5. Leningrad: Hydrometeoizdat, 1970: 146 p. [In Russian].

17. Katalog lednikov SSSR. USSR Glacier Inventory. V. 8. Pt. 6–7. Leningrad: Hydrometeoizdat, 1973: 96 p. [In Russian].

18. Katalog lednikov SSSR. USSR Glacier Inventory. V. 8. Pt. 8–9. Leningrad: Hydrometeoizdat, 1976: 76 p. [In Russian].

19. Katalog lednikov SSSR. USSR Glacier Inventory. V. 8. Pt. 10–11. Leningrad: Hydrometeoizdat, 1977: 72 p. [In Russian].

20. Katalog lednikov SSSR. USSR Glacier Inventory. V. 9. Is. 1. Pt. 2–6. Leningrad: Hydrometeoizdat, 1975: 87 p. [In Russian].

21. Podozersky K.I. Glaciers of the Caucasus Range. Izvestiya Kavkazskogo otdela Imperatorskogo Russkogo geograficheskogo obshchestva. News of the Caucasus Department of the Imperial Russian Geographical Society. Tiflis. 1911, 29 (1): 200 p. [In Russian].

22. Desinov L.V. Surge of Kolka glacier in 2002. Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2004, 4 (3): 72–87. [In Russian].

23. Tutubalina O.V., Chernomorets S.S., Petrakov D.A. Kolka glacier before the 2002 collapse: new data. Kriosfera Zemli. Earth’s Cryosphere. 2005, 9 (4): 62–71. [In Russian].

24. Vaskov I.M. Katastroficheskie obvaly: proiskhozhdenie i prognoz. Catastrophic collapses: origin and prognosic. Vladikavkaz: «MAVR», 2016: 370 p. [In Russian].

25. Popovnin V.V., Petrakov D.A., Tutubalina O.V., Chernomorets S.S. The 2002 glacial catastrophe in North Ossetia. Kriosfera Zemli. Earth’s Cryosphere. 2003, 7 (1): 3–17. [In Russian].

26. Huggel C., Zgraggen-Oswald S., Haeberli W., Kaab A., Polkvoj A., Galushkin I., Evans S.G. The 2002 rock/ice avalanche at Kolka/Karmadon, Russian Caucasus: assessment of extraordinary avalanche formation and mobility, and application of QuickBird satellite imagery. Natural Hazards and Earth System Sciences. 2005, 5: 173–187.

27. Kotlyakov V.M., Rototaeva O.V., Nosenko G.A., Desinov L.V., Osokin N.I., Chernov R.A. Karmadonskaya katastrofa: chto sluchilos i chego zhdat dalshe. Karmadon catastrophe: what happened and what we should wait for in future. Мoscow: «Kodeks» Publishing House, 2014: 184 p. [In Russian].

28. Nikitin M.Yu., Goncharenko O.A., Galushkin I.V., Dynamics and stages in the development of the Genaldon ice-rock flow on the basis of remote sensing analysis. Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2007, 7 (3): 2–15. [In Russian].

29. Petrakov D.A., Drobyshev V.N., Aleinikov A.A., Aristov K.A., Tutubalina O.V., Chernomorets S.S. Changes in the area of Genaldon glacial disaster in 2002–2010. Kriosfera Zemli. Earth’s Cryosphere. 2013, 17 (1): 35–46. [In Russian].

30. Kotlyakov V.M., Rototaeva O.V., Nosenko G.A., Osokin N.I., Chernov R.A. Dynamics of the Kolka Glacier recovery processes. Lednik Kolka: vchera, segodnya, zavtra. Kolka Glacier: Past, Present, Future. Eds.: Yu.G. Leonov, V.B. Zaalishvili. Vladikavkaz: CGI VSC RAS and RNO, 2014: 233–238. [In Russian].

31. Tavasiev R.A. Mayli and Kolka glaciers (Central Caucasus). Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2012, 12 (3): 37–45. [In Russian].

32. Rototayev K.P., Khodakov V.G., Krenke A.N. Issledovanie pulsiruyushchego lednika Kolka. A study of the surging Kolka Glacier. Moscow: Nauka, 1983: 168 p. [In Russian].

33. Chernomorets S.S., The new «Kazbek blockage» on May 17, 2014. Priroda. Nature. 2014, 7: 67–72. [In Russian].

34. Drobushev V.N., Torchinov H-M.Z., Tutubalina O.V., Hubaev H.M. Main topographical data and kinematics of the Devdorakskiy collapse on May 17, 2014. Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2014, 14 (4): 30–41. [In Russian].

35. Tavasiev R.A. Catastrophic collapses from the Devdorak Glacier. Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2015, 15 (1): 50–57. [In Russian].

36. Chernomorets S.S., Savernyuk E.A., Petrakov D.A., Dokukin M.D., Gotsiridze G., Gavardashvili G.V., Drobyshev V.N., Tutubalina O.V., Kolchin A.A., Zaporozhchenko E.V., Kamenev N.A., Kamenev V.A., Kaab A., Kargel J., Huggel C. Ice-rock avalanche and consequent debris flow in the Devdorak gorge (Mt. Kazbek, Caucasus, Georgia) in 2014. Debris flows: risks, forecast, protection: Materials of IV International Conference (Russia, Irkutsk – Arshan village (The Republic of Byriatia), September 6–10, 2016. Irkutsk: Sochava Institute of Geography, Siberian Branch of the RAS, 2016: 244–248. [In Russian].

37. Dokukin M.D, About a rock avalanche near the Bartuycete glacier (Central Caucasus). Izvestiya vsesoyuznogo geograficheskogo obshchestva. Proceedings of the All-Union Geographical Society. 1988, 120 (4): 348–353. [In Russian].

38. Savernyuk E.A. Features of the morphology and dynamics of landslides on the Bartuycete glacier (Republic of North Ossetia – Алания). Trudy Vysokogornogo geofizicheskogo instituta. Proc. of the High Mountain Geophysical Institute. 2013, 97: 36–40. [In Russian].

39. Tavasiev R.A. The degradation of Karaugom glacier. Part 1. The dynamics of the glacier’s retreat. Vestnik Vladikavkazskogo Nauchnogo Centra. Bulletin of Vladikavkaz Scientific Centre. 2017, 17 (4): 19–27. [In Russian].

40. Olyunin V.N. On the history of glaciation in the southeast of the mountainous part of the Kabardin ASSR Trudy Instituta geografii AN SSSR. Proc. of the Institute of Geography, USSR Academy of Sciences. 1953, 58 (10): 90–178. [In Russian].

41. Tavasiev. R.A. Surging Mosota Glacier in Digoria (Central Caucasus) Dangerous natural and anthropogenic geological processes in the mountain and foothill territories of the Northern Caucasus. Trudy II Mezhdunarodnoy nauchnoprakticheskoy konferentsii, posvyashchyonnoy 10‑letiyu so dnya sozdaniya Vladikavkazskogo nauchnogo tsentra RAN i Pravitel'stva RSO‑A. Proc. of the II Intern. Scientific and Practical Conf. dedicated to the 10th anniversary of the founding of the Vladikavkaz Scientific Center of the Russian Academy of Sciences and the Government of North Ossetia-Alania. Vladikavkaz, 2010: 225–235. [In Russian].

42. Reznichenko N.V., Davies T.R.H., Alexander D.J. Effects of rock avalanches on glacier behaviour and moraine formation. Geomorphology. 2011, 132: 327–338. https://doi.org/10.1016/j.geomorph.2011.05.019.

43. Paul F. Repeat Glacier Collapses and Surges in the Amney Machen Mountain Range, Tibet, Possibly Triggered by a Developing Rock-Slope Instability. Remote Sensing. 2019, 11: 708 р. https://doi.org/10.3390/rs11060708.

44. Kidyaeva V.M., Krylenko I.N., Krylenko I.V., Petrakov D.A., Chernomorets S.S. Water level fluctuations in mountain glacier lakes in the Elbrus region. Georisk. 2013, 3: 20–27. [In Russian].

45. Dokukin M.D., Savernyuk E.A. On the possibility of assessing the threat of rock avalanches (using the example of the valley of the Khargabakhk river, Chechen Republic). V mire nauchnykh otkrytiy. In the world of scientific discoveries. 2010, 3 (09), 4: 146–151. [In Russian].